DISC-TYPE IRONLESS PERMANENT MAGNET SYNCHRONOUS GENERATOR POWERED BY AUXILIARY POWER SUPPLY

Abstract

Provided is a disc-type ironless permanent magnet synchronous generator powered by an auxiliary power supply, which comprises a stator coil disc and a pair of permanent magnet rotor discs (1) positioned on two sides of the stator coil disc and arranged with a gap therebetween, a circle of main coils (3) are fixedly arranged on the stator coil disc around a center of the disc, the main coil is a main winding of an electric motor to output electric energy, an auxiliary winding independent from the main winding is arranged on a circumference formed by the main coils (3) in a surrounding manner, and output power of the auxiliary winding is less than output power of the main winding.

Claims

1. A disc-type ironless permanent magnet synchronous generator powered by an auxiliary power supply, comprising a stator coil disc and a pair of permanent magnet rotor discs (1) positioned on two sides of the stator coil disc and arranged with a gap therebetween, the stator coil disc being coaxial with the permanent magnet rotor disc (1), a circle of main coils (3) being fixedly arranged on the stator coil disc around a center of the disc, and the main coil being a main winding of an electric motor to output electric energy, wherein an auxiliary winding independent from the main winding is arranged on a circumference formed by the main coils (3) in a surrounding manner, and output power of the auxiliary winding is less than output power of the main winding.

2. The disc-type ironless permanent magnet synchronous generator powered by the auxiliary power supply according to claim 1, wherein the auxiliary winding is provided with one or more independent auxiliary coils (4), and each auxiliary coil is composed of an independent coil.

3. The disc-type ironless permanent magnet synchronous generator powered by the auxiliary power supply according to claim 2, wherein a number of the auxiliary coils (4) is greater than or equal to 1 and less than or equal to 3m, wherein m is a number of phases of the electric motor, and the main coil and the auxiliary coil form an unevenly distributed circumference.

4. The disc-type ironless permanent magnet synchronous generator powered by the auxiliary power supply according to claim 2, wherein the main winding is divided into multiple phases, which are distributed in a central symmetry relative to the center of the stator coil disc, and on the same layer of winding disc, the auxiliary coil (4) is separately arranged between coils of different phases of the main winding.

5. The disc-type ironless permanent magnet synchronous generator powered by the auxiliary power supply according to claim 2, wherein a sum of pitches occupied by the main coils is greater than a sum of pitches occupied by the auxiliary coils; the pitch of the main coil is expressed as: y1=[(360−(A+B)×a1)−A×y2]/B, wherein y1 represents the pitch of the main coil, expressed in degrees, A represents a number of the auxiliary coils, B represents a number of the main coils, a1 represents an angle occupied by an interval between adjacent coils, y2 represents the pitch of the auxiliary coil, expressed in degrees, and a value of y2 ranges from 1 to 360/B.

6. The disc-type ironless permanent magnet synchronous generator powered by the auxiliary power supply according to claim 2, wherein a plurality of auxiliary coils are used separately, or the plurality of auxiliary coils are connected into a loop.

7. The disc-type ironless permanent magnet synchronous generator powered by the auxiliary power supply according to claim 2, wherein a sum of total power of the auxiliary coils is less than total power of the main coils.

8. The disc-type ironless permanent magnet synchronous generator powered by the auxiliary power supply according to claim 7, wherein the sum of the total power of the auxiliary coils is less than one third of the total power of the main coils.

Description

DESCRIPTION OF THE DRAWINGS

[0014] FIG. 1 is a perspective view of a topological structure of an embodiment of an electric motor according to the present invention.

[0015] FIG. 2 is a schematic structural diagram of an embodiment of a stator coil winding of the electric motor according to the present invention.

[0016] In the drawings, 1 refers to permanent magnet rotor disc, 2 refers to permanent magnet, 3 refers to main coil, and 4 refers to auxiliary coil.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0017] As shown in FIG. 1 and FIG. 2, an embodiment provided by the present invention is described by taking an axial ironless three-phase permanent magnet disc-type generator with 18 main coils of three phases and 20 pairs of magnetic poles as an example.

[0018] The disc-type ironless permanent magnet synchronous generator powered by the auxiliary power supply comprises a coaxial stator coil disc and a pair of permanent magnet rotor discs 1 positioned on two sides of the stator coil disc and arranged with a gap therebetween. The pair of permanent magnet rotor discs 1 are respectively provided with a circle of permanent magnets 2 of the same number fixedly arranged around a center of the permanent magnet rotor disc, the permanent magnets 2 on the pair of permanent magnet rotor discs 1 are axially aligned in pairs, and a pair of aligned magnetic poles are arranged in the same direction, which is a common structure of the disc-type electric motor.

[0019] A circle of main coils 3 are fixedly arranged on the stator coil disc around the center of the disc, the main coil 3 is a main winding of an electric motor to output electric energy, an auxiliary winding independent from the main winding is arranged on a circumference on which the main coils 3 are located, and output power of the auxiliary winding is less than output power of the main winding. Therefore, a wire diameter, an output voltage, and coil volume and shape of the auxiliary winding are all different from those of the main winding, the auxiliary winding may be a single auxiliary coil 4 or a plurality of auxiliary coils 4, and each auxiliary winding may usually be composed of an independent coil.

[0020] For a multi-phase output auxiliary winding, a sum of total power of the auxiliary coils 4 is less than total power of the main coils. Further, the sum of the total power of the auxiliary coils 4 is less than one third of the total power of the main coils. The auxiliary coil usually supplies power to a control system of the electric motor itself, and only needs low power to output.

[0021] It is impossible for symmetrical distribution of a single auxiliary coil, and if there are a plurality of auxiliary coils, the auxiliary coils may or may not be centrally symmetrically distributed relative to the center of the stator disc. Since the main coil and the auxiliary coil have different physical parameters, the main coil and the auxiliary coil form an unevenly distributed circumference.

[0022] Specifically, a number of the auxiliary coils is greater than or equal to 1 and less than or equal to 3m, wherein m is a number of phases of the main winding of the electric motor. A three-phase electric motor may be provided with 1 to 9 auxiliary coils, and a four-phase electric motor may be provided with 1 to 12 auxiliary coils. The main coil of each phase is composed of a plurality of coils, and a number of the auxiliary coils is less than that of the main coil. It is inappropriate to arrange too many auxiliary coils, so as to prevent occupying too much space of the main coil, which can greatly reduce a winding coefficient of the main coil, thereby affecting power supply power of the main power supply.

[0023] In FIG. 2, as an embodiment, the main winding is divided into three phases. When designing the stator winding, it is necessary to ensure that three-phase voltages of the main power supply are spatially deviated from each other by an electrical angle of 120 degrees, and the three-phase voltages are balanced. The three-phase winding constitutes the main winding which is centrally symmetrical relative to the center of the disc.

[0024] The auxiliary coils are separately distributed between coils of different phases of the main winding. The plurality of auxiliary coils may be combined and connected in series and parallel with each other to output, or output independently. The plurality of independent auxiliary coils may have flexible and variable output settings as needed.

[0025] Positions occupied by the auxiliary coils may be standardized as follows: a sum of pitches occupied by the main coils is greater than a sum of pitches occupied by the auxiliary coils. The pitch of the main coil is expressed as:

y1=[(360−(A+B)×a1)−A×y2]/B.

[0026] Wherein, y1 represents the pitch of the main coil, expressed in degrees, A represents a number of the auxiliary coils, B represents a number of the main coils, a1 represents an angle occupied by an interval between adjacent coils, y2 represents the pitch of the auxiliary coil, expressed in degrees, and a value of y2 ranges from 1 to 360/B. This expression shows that the main coil and the auxiliary coil have different pitches, and the main coil and the auxiliary coil respectively keep a consistent pitch. For example, the main winding in the drawings is 18 coil slots of three phases and is provided with three auxiliary coils, and the above formula may be expressed as:

y1=[(360−21×a1)−3×y2]/18.

[0027] The stator winding coil of the generator is formed by winding an enameled wire. Preferably, in order to enhance the insulation of the winding of the electric motor, the wound coil is processed by a paint dipping technology. Preferably, in order to enhance a mechanical property of the stator of the electric motor, the processed coil is placed on a non-magnetic stator frame, and the coil is reliably fixed on the stator frame by using an adhesive. The non-magnetic stator frame should have good insulation, mechanical toughness and mechanical strength.

[0028] Compared with the prior art, the generator of the present invention may output a plurality of electric energies of multiple voltage levels. Compared with a generator with a traditional structure, the present invention is added with several low-voltage power supplies under a condition of slightly reducing power of an output power supply, which may provide low-power electric energy for auxiliary equipment of a system, without occupying output of the main coil of one phase, thereby avoiding the imbalance of output power and the reduction of output efficiency caused by occupying the main coil.